As telecommunications providers continue the rollout of optical fibre and 5G mobile coverage across Europe, implementing noise protection for the air conditioning systems used in point of presence (PoP) and radio access network (RAN) stations is vital. Uwe Kudszus, product manager, at STULZ explains how effective noise control not only ensures compliance with legislation but also reduces disturbance in urban environments.

Full-fibre networks are now available to the majority of Europeans. According to the FTTH Council Europe, while a few countries including Belgium, Germany, Greece and the Czech Republic are lagging behind, nearly everyone in Spain, Portugal and France has access to full-fibre, with overall penetration rates expected to pass 90 per cent in both the European Union (EU) and the UK by 2028. Meanwhile, figures from the 5G Observatory found that 81 per cent of the EU population was covered by at least one basic 5G network in 2023, while in the UK Ofcom estimated that 85-93 per cent of premises could get 5G coverage outdoors.

Close to home

In addition to laying countless kilometres of cable, a major challenge for operators concerns the construction of the numerous PoP and RAN stations required to connect backbones to various access networks. In densely populated urban areas, the shelters housing these PoP and RAN stations are usually located in the immediate vicinity of residential or mixed use areas. At the same time, the development of new residential areas is leading to stations being built close to buildings in rural locations.

PoP and RAN stations contain sensitive IT and networking components, so a constant internal temperature must be ensured to protect the technology from the elements and maximise uptime. In many cases, this is only possible using mechanical refrigeration. As a result, the noise generated by compressors, pumps and other components should be considered at the planning stage to ensure that the systems comply with all relevant noise protection regulations.

What is sound?

In acoustics, a distinction is made between sound power and sound pressure. Sound power is the total acoustic energy produced by a sound source. Conversely, sound pressure is a location dependent variable and is measured in dB(A) according to the A weighting curve, which is based on the human perception of sound and mimics the ear's response.

If sound pressure increases by 10dB(A), it is perceived by humans as being approximately twice as loud. In terms of measurement technology, however, sound pressure doubles with an increase of just 3dB(A).

Additionally, the sound power of several sound sources can add up to a higher overall sound pressure level. Two identical sound sources lead to an increase of 3dB(A), while four identical sound sources to an increase of 6dB(A). To achieve an increase of 10dB(A), 10 identical sound sources would be required. However, if one sound source is more than 10dB(A) quieter than another, it usually does not lead to a significant increase – the total sound pressure of both sound sources corresponds to the sound pressure of the louder sound source.

The structural relationship between the sound source and the point of sound impact is also relevant. Factors like reflections and absorption by buildings or vegetation can either increase or decrease sound pressure at the impact site, depending on specific local conditions.

How does sound affect people?

Human perception of sound varies widely from person to person, with familiarity playing a crucial role. Sounds that are well-known or expected tend to be perceived as less disruptive than unfamiliar or surprising noises, even when both have the same sound pressure level.

This phenomenon relates to how the brain processes and interprets auditory information. When a sound is familiar, the brain can predict its pattern and duration, reducing the sense of intrusion. In contrast, unexpected sounds trigger heightened alertness, as the brain interprets them as potential threats, leading to increased discomfort or annoyance.

For people who are sensitive to noise, a volume of 25-30dB(A), (the noise level of quiet speech), can be enough to reduce the restfulness of sleep. Continuous noise creates stress and impairs general wellbeing, with 60-65dB(A), (the noise level of shouting), having the potential to cause serious health problems. However, hearing damage usually only occurs at sustained noise levels of at least 85dB(A).

Noise protection regulations

In Europe, noise protection for residential areas is governed by a combination of EU directives and national laws. The Environmental Noise Directive (END) 2002/49/EC serves as a foundational framework, requiring EU member states to assess and manage environmental noise. It mandates the creation of noise maps and action plans for urban areas with populations exceeding 100,000, focusing on long-term noise reduction strategies.

Individual countries have implemented these guidelines through national regulations, often specifying permissible noise levels and setting distinct limits for daytime, evening and nighttime hours to protect residential zones. In the UK, this directive has been transposed into the Environmental Noise (England) Regulations 2006 and its subsequent amendments.

Residential areas are typically classified based on land use and sensitivity to noise. These classifications influence permissible noise limits, with stricter thresholds for quiet zones such as hospitals, schools and purely residential districts, compared to mixed use or commercial areas. Typical daytime limits range between 50-65dB(A), while nighttime limits are more stringent, often between 40-55dB(A).

To calculate noise exposure, standardised approaches like the day-evening-night level (Lden) methodology are used. Lden is a 2002 European standard that addresses factors such as the type of noise source, duration and frequency over the course of an entire day. Legal enforcement involves regular monitoring, public reporting and the ability for residents to seek remediation if noise levels exceed regulatory limits. Local authorities play a significant role in enforcing noise limits and providing guidance on acceptable noise levels to protect public health and wellbeing.

Several standards must also be observed when preparing noise forecasts and carrying out noise measurements. These include ISO 9613-2, which provides a method for predicting the attenuation of sound as it travels outdoors from a noise source to a receiver, while ISO 12354-4 specifies a calculation model to estimate the sound power level radiated by a building's envelope due to airborne sound inside the building. ISO 3746 outlines methods for determining sound power levels of noise sources using sound pressure measurements.

Better sound insulation pays off

Noise protection technology minimises complaints from residents, increases acceptance of PoP and RAN sites among the population, avoids expensive retrofitting in the event of stricter regulations and protects against legal disputes. Noise protection is therefore an important factor in strategic planning for fibre optic and mobile communications providers. The tightness, mass and insulation thickness of shelter walls are crucial for sound insulation. By using a construction method optimised for sound insulation, sound transmission can be reduced to a minimum.

Early investment in high quality noise protection can save costs in the long-term and increase flexibility in the choice of location. This is particularly important in densely populated locations, where more and more installation areas are required for PoP and RAN stations.

Cities are becoming ever more densely populated and new residential areas are constantly being developed. As a result, existing PoP stations might need to be retrofitted with noise protection equipment if they are located near a new residential area. Thinking ahead makes a great deal of strategic sense in this respect, as investing in noise protection solutions that are as future proof as possible can save significant time, money and effort over the medium- to long-term.

Effective sound insulation measures

To minimise the noise created by PoP and RAN base stations, the use of silencers is recommended. These can be mounted on the air inlets and outlets of shelter containers. A measurement carried out on behalf of a STULZ customer in The Netherlands showed that the integration of silencers reduced sound power by up to 12dB(A) through their integration with a specific outdoor shelter, air conditioning unit and operating mode.

This type of optimal configuration is effective to such an extent that stations are able to operate well below any statutory noise protection requirements and are hardly perceptible acoustically. Although measures such as these do mean higher capital expenditure in the short-term, they pay off in the long-term through flexible siting and the acceptance of expansion measures among residents.

Even in existing areas that must comply with stricter limit values due to subsequent building densification, noise output can be effectively reduced by retrofitting silencers. In addition, the average total operating time of compressors, pumps and other components can be reduced in existing systems by retrofitting a free cooling module. Free cooling modules can be combined with air conditioning systems from various manufacturers, which not only reduces the overall system noise level but also saves energy costs related to cooling.

It makes sense to plan ahead

For modern telecommunications networks, the early integration of noise reduction technologies during the planning of PoP and RAN locations is essential, both operationally and economically. It acts as a strategic lever that reconciles technical feasibility, energy efficiency, future proofing and social responsibility.

Those who focus exclusively on the minimum legal requirements when it comes to noise protection run the risk of having to carry out expensive retrofitting in the event of stricter noise protection legislation. Cutting edge solutions such as hybrid cooling systems with automated free cooling operation or modular retrofittable silencers offer a decisive advantage, as they not only reduce noise emissions but also lower operating costs through efficient load distribution.

Work with a trusted partner

Companies such as STULZ can assist telecommunications providers by offering comprehensive solutions that cover everything from acoustic site analysis to the development of prototypical energy efficient shelter systems. This integrated approach not only focuses on noise reduction but also promotes sustainable infrastructure growth – an essential factor for maintaining regulatory compliance and achieving the long-term acceptance of PoP and RAN stations in densely populated neighbourhoods.